Illuminated mircorsurgical probe

ABSTRACT

An illuminated microsurgical probe may include a handle, a diffuser, an aspiration conduit, and an optic fiber bundle. The diffuser may include a diffuser distal end, a diffuser proximal end, and a diffuser inner bore. The handle may include a handle distal end, a handle proximal end, and a handle inner bore. The aspiration conduit may include an aspiration conduit distal end and an aspiration conduit proximal end. The aspiration conduit distal end may be disposed in the diffuser inner bore and the aspiration conduit proximal end may be disposed in the handle inner bore. The optic fiber bundle may include an optic fiber bundle distal end and an optic fiber bundle proximal end. The optic fiber bundle distal end may be disposed in the diffuser inner bore.

CROSS-REFERENCE TO RELATED APPLICATIONS

This Application claims the benefit of U.S. Provisional Application No.62/189,508, filed Jul. 7, 2015.

FIELD OF THE INVENTION

The present disclosure relates to a microsurgical probe, and, moreparticularly, to an illuminated microsurgical probe.

BACKGROUND OF THE INVENTION

A variety of surgical procedures require removal of debris from asurgical site, e.g., blood, irrigation fluid, tissue, bone, etc., mayrequire removal from a surgical site during a surgical procedure. Manymicrosurgical procedures require illumination of a surgical site toallow a surgeon to adequately visualize the surgical site during asurgical procedure. Some microsurgical procedures may require removal ofdebris from a surgical site and illumination of the surgical site. Forexample, a neurosurgical procedure for a cavernous malformation and aspinal surgical procedure for a laminectomy may require both removal ofdebris from a surgical site and illumination of the surgical site.Accordingly, there is a need for a microsurgical probe having bothaspiration and illumination functionality.

BRIEF SUMMARY OF THE INVENTION

In one or more embodiments, an illuminated microsurgical probe maycomprise a handle, a diffuser, an aspiration conduit, and an optic fiberbundle. Illustratively, the diffuser may comprise a diffuser distal end,a diffuser proximal end, and a diffuser inner bore. In one or moreembodiments, the handle may comprise a handle distal end, a handleproximal end, and a handle inner bore. Illustratively, the aspirationconduit may comprise an aspiration conduit distal end and an aspirationconduit proximal end. In one or more embodiments, the aspiration conduitdistal end may be disposed in the diffuser inner bore and the aspirationconduit proximal end may be disposed in the handle inner bore.Illustratively, the optic fiber bundle may comprise an optic fiberbundle distal end and an optic fiber bundle proximal end. In one or moreembodiments, the optic fiber bundle distal end may be disposed in thediffuser inner bore.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and further advantages of the present invention may be betterunderstood by referring to the following description in conjunction withthe accompanying drawings in which like reference numerals indicateidentical or functionally similar elements:

FIGS. 1A, 1B, 1C, 1D, 1E, and 1F are schematic diagrams illustrating ahandle;

FIGS. 2A and 2B are schematic diagrams illustrating a swivel;

FIGS. 3A, 3B, 3C, 3D, 3E, and 3F are schematic diagrams illustrating adiffuser;

FIGS. 4A and 4B are schematic diagrams illustrating an aspirationconduit;

FIGS. 5A, 5B, and 5C are schematic diagrams illustrating an assembledhand-piece;

FIGS. 6A and 6B are schematic diagrams illustrating a distal retainer;

FIGS. 7A and 7B are schematic diagrams illustrating a proximal retainer;

FIG. 8 is a schematic diagram illustrating an exploded view of anilluminated microsurgical probe assembly;

FIG. 9 is a schematic diagram illustrating an assembled illuminatedmicrosurgical probe.

DETAILED DESCRIPTION OF AN ILLUSTRATIVE EMBODIMENT

FIGS. 1A, 1B, 1C, 1D, 1E, and 1F are schematic diagrams illustrating ahandle 100. FIG. 1A illustrates an isometric view of handle 100.Illustratively, handle 100 may comprise a handle distal end 101, ahandle proximal end 102, a barb 103, a distal sleeve interface 104, avent 105, an optic fiber bundle jacketing housing 110, and a handledistal chamber 115. In one or more embodiments, optic fiber bundlejacketing housing 110 may comprise an optic fiber bundle jacketinghousing distal end 111 and an optic fiber jacketing housing proximal end112. Illustratively, optic fiber bundle jacketing housing distal end 111may be adjacent to handle distal end 101. In one or more embodiments,optic fiber bundle jacketing housing proximal end 112 may be adjacent todistal sleeve interface 104. FIG. 1B illustrates a top view of handle100. Illustratively, vent 105 may comprise a vent distal end 106 and avent proximal end 107. In one or more embodiments, vent 105 may have avariable width, e.g., vent 105 may have a first width at vent distal end106 and vent 105 may have a second width at vent proximal end 107.Illustratively, the second width may be greater than the first width. Inone or more embodiments, the first width may be greater than the secondwidth. FIG. 1C illustrates a cross-sectional view in a transverse planeof handle 100. FIG. 1D illustrates a cross-sectional view in a sagittalplane of handle 100. In one or more embodiments, handle 100 may comprisea handle distal chamber 115, a handle focused taper 116, a handle innerbore 117, and a handle proximal chamber 118. FIG. 1E illustrates a frontview of handle 100. FIG. 1F illustrates a back view of handle 100. Inone or more embodiments, handle 100 may be may be manufactured from anysuitable material, e.g., polymers, metals, metal alloys, etc., or fromany combination of suitable materials.

FIGS. 2A and 2B are schematic diagrams illustrating a swivel 200. FIG.2A illustrates an isometric view of swivel 200. In one or moreembodiments, swivel 200 may comprise a swivel distal end 201, swivelproximal end 202, an outer swivel component 210, and an inner swivelcomponent 220. FIG. 2B illustrates a cross-sectional view in a sagittalplane of swivel 200. Illustratively, outer swivel component 210 maycomprise an outer swivel component distal end 211, an outer swivelcomponent proximal end 212, and an outer swivel component inner bore215. In one or more embodiments, inner swivel component 220 may comprisean inner swivel component distal end 221, an inner swivel componentproximal end 222, and an inner swivel component inner bore 225.Illustratively, a portion of inner swivel component 220 may be disposedwithin a portion of outer swivel component 210, e.g., inner swivelcomponent distal end 221 may be disposed within a portion of outerswivel component 210. In one or more embodiments, a portion of innerswivel component 220 may be disposed within a portion of outer swivelcomponent 210 wherein inner swivel component proximal end 222 is swivelproximal end 202 and outer swivel component distal end 211 is swiveldistal end 201.

Illustratively, a portion of inner swivel component 220 may be disposedwithin a portion of outer swivel component 210 wherein inner swivelcomponent distal end 221 is disposed between outer swivel componentdistal end 211 and outer swivel component proximal end 212. In one ormore embodiments, a portion of inner swivel component 220 may bedisposed within a portion of outer swivel component 210 wherein outerswivel component proximal end 212 is disposed between inner swivelcomponent distal end 221 and inner swivel component proximal end 222.Illustratively, a portion of inner swivel component 220 may be fixedwithin a portion of outer swivel component 210 wherein inner swivelcomponent 220 is configured to rotate relative to outer swivel component210. In one or more embodiments, a portion of inner swivel component 220may be fixed within a portion of outer swivel component 210 whereinouter swivel component 210 is configured to rotate relative to innerswivel component 220. Illustratively, a portion of inner swivelcomponent 220 may be disposed in a portion of outer swivel component 210wherein inner swivel component inner bore 225 is aligned with outerswivel component inner bore 215, e.g., a portion of inner swivelcomponent 220 may be disco posed in a portion of outer swivel component210 wherein inner swivel component inner bore 225 and outer swivelcomponent inner bore 215 comprise a single inner bore of swivel 200. Inone or more embodiments, swivel 200 may be may be manufactured from anysuitable material, e.g., polymers, metals, metal alloys, etc., or fromany combination of suitable materials.

FIGS. 3A, 3B, 3C, 3D, 3E, and 3F are schematic diagrams illustrating adiffuser 300. FIG. 3A illustrates an isometric view of diffuser 300. Inone or more embodiments, diffuser 300 may comprise a diffuser distal end301, a diffuser proximal end 302, a first distal taper 311 and adiffuser inner bore 315. FIG. 3B illustrates a cross-sectional view in asagittal plane of diffuser 300. Illustratively, diffuser 300 maycomprise a first atraumatic offset 303 and a first diffusion notch 321.In one or more embodiments, first atraumatic offset 303 may beconfigured to reduce a risk of unintentional trauma during a surgicalprocedure. For example, first distal taper 311 may be configured toreduce a surface area of diffuser distal end 301 which may increase arisk of unintentional trauma during a surgical procedure, e.g., reducinga surface area of diffuser distal end 301 may increase a risk of cuttinga tissue during an aspiration of a surgical site. In one or moreembodiments, first atraumatic offset 303 may be configured to decrease arisk of cutting a tissue during an aspiration of a surgical site, e.g.,first atraumatic offset 303 may be configured to decrease a risk ofcutting a tissue during an aspiration of a surgical site by increasing asurface area of diffuser distal end 301. Illustratively, firstatraumatic offset 303 may have a length in a range of 0.02 to 0.04inches, e.g., first atraumatic offset 303 may have a length of 0.03inches. In one or more embodiments, first atraumatic offset 303 may havea length of less than 0.02 inches or greater than 0.04 inches.

Illustratively, diffuser 300 may be configured to diffuse light, e.g.,diffuser 300 may be configured to diffuse light to illuminate a surgicalsite. In one or more embodiments, diffuser 300 may be configured todiffuse light by diffuse reflection. Illustratively, diffuser 300 may bemay be manufactured from any suitable material, e.g., polymers, metals,metal alloys, etc., or from any combination of suitable materials. Inone or more embodiments, diffuser 300 may be manufactured from amaterial configured to increase an efficiency of diffuse reflection.Illustratively, diffuser 300 may be manufactured from an opticallytransparent material, e.g., diffuser 300 may be manufactured frompolycarbonate, acrylic, etc. In one or more embodiments, diffuser 300may be manufactured from a material having an index of refraction thatis similar to an index of refraction of optic fiber bundle 850, e.g.,diffuser 300 may be manufactured from a material having an index ofrefraction that is not more than 10.0 to 30.0 percent less than an indexof refraction of optic fiber bundle 850. Illustratively, diffuser 300may be manufactured from a material having an index of refraction thatis not more than 10.0 to 30.0 percent greater than an index ofrefraction of optic fiber bundle 850. In one or more embodiments,diffuser 300 may be manufactured from a material having an index ofrefraction that is not more than 10.0 percent less than an index ofrefraction of optic fiber bundle 850, e.g., diffuser 300 may bemanufactured from a material having an index of refraction that is notmore than 10.0 percent greater than an index of refraction of opticfiber bundle 850. Illustratively, first diffusion notch 321 may beconfigured to diffuse light, e.g., first diffusion notch 321 may beconfigured to diffuse light by diffuse reflection. In one or moreembodiments, diffuser 300 may comprise a plurality of first diffusionnotches 321, e.g., diffuser 300 may comprise a plurality of firstdiffusion notches 321 wherein each first diffusion notch 321 of theplurality of first diffusion notches 321 is configured to diffuse light.For example, a first particular first diffusion notch 321 of theplurality of first diffusion notches 321 may be configured to diffuse anincident ray of light at a first plurality of angles creating aplurality of first non-incident rays of light and a second particularfirst diffusion notch 321 of the plurality of first diffusion notches321 may be configured to diffuse a first non-incident ray of light ofthe plurality of first non-incident rays of light at a second pluralityof angles creating a plurality of second non-incident rays of light.

FIG. 3C illustrates an isometric view of diffuser 300. In one or moreembodiments, diffuser 300 may comprise a diffuser distal end 301, adiffuser proximal end 302, a second distal taper 312, a diffuser innerbore 315, and a diffusion indentation 330. Illustratively, diffusionindentation 330 may comprise a diffusion indentation distal end 331, adiffusion indentation proximal end 332, a diffusion indentation distalgradient increase 333, and a diffusion indentation proximal gradientincrease 334. FIG. 3D illustrates a cross-sectional view in a sagittalplane of diffuser 300. Illustratively, diffuser 300 may comprise asecond atraumatic offset 304 and a second diffusion notch 322. In one ormore embodiments, second atraumatic offset 304 may be configured toreduce a risk of unintentional trauma during a surgical procedure. Forexample, second distal taper 312 may be configured to reduce a surfacearea of diffuser distal end 301 which may increase a risk ofunintentional trauma during a surgical procedure, e.g., reducing asurface area of diffuser distal end 301 may increase a risk of cutting atissue during an aspiration of a surgical site. In one or moreembodiments, second atraumatic offset 304 may be configured to decreasea risk of cutting a tissue during an aspiration of a surgical site,e.g., second atraumatic offset 304 may be configured to decrease a riskof cutting a tissue during an aspiration of a surgical site byincreasing a surface area of diffuser distal end 301. Illustratively,second atraumatic offset 304 may have a length in a range of 0.02 to0.04 inches, e.g., second atraumatic offset 304 may have a length of0.03 inches. In one or more embodiments, second atraumatic offset 304may have a length of less than 0.02 inches or greater than 0.04 inches.

Illustratively, diffuser 300 may be configured to diffuse light, e.g.,diffuser 300 may be configured to diffuse light to illuminate a surgicalsite. In one or more embodiments, diffuser 300 may be configured todiffuse light by diffuse reflection. Illustratively, diffuser 300 may bemay be manufactured from any suitable material, e.g., polymers, metals,metal alloys, etc., or from any combination of suitable materials. Inone or more embodiments, diffuser 300 may be manufactured from amaterial configured to increase an efficiency of diffuse reflection.Illustratively, diffuser 300 may be manufactured from an opticallytransparent material, e.g., diffuser 300 may be manufactured frompolycarbonate, acrylic, etc. In one or more embodiments, diffuser 300may be manufactured from a material having an index of refraction thatis similar to an index of refraction of optic fiber bundle 850, e.g.,diffuser 300 may be manufactured from a material having an index ofrefraction that is not more than 10.0 to 30.0 percent less than an indexof refraction of optic fiber bundle 850. Illustratively, diffuser 300may be manufactured from a material having an index of refraction thatis not more than 10.0 to 30.0 percent greater than an index ofrefraction of optic fiber bundle 850. In one or more embodiments,diffuser 300 may be manufactured from a material having an index ofrefraction that is not more than 10.0 percent less than an index ofrefraction of optic fiber bundle 850, e.g., diffuser 300 may bemanufactured from a material having an index of refraction that is notmore than 10.0 percent greater than an index of refraction of opticfiber bundle 850. Illustratively, second diffusion notch 322 may beconfigured to diffuse light, e.g., second diffusion notch 322 may beconfigured to diffuse light by diffuse reflection. In one or moreembodiments, diffuser 300 may comprise a plurality of second diffusionnotches 322, e.g., diffuser 300 may comprise a plurality of seconddiffusion notches 322 wherein each second diffusion notch 322 of theplurality of second diffusion notches 322 is configured to diffuselight. For example, a first particular second diffusion notch 322 of theplurality of second diffusion notches 322 may be configured to diffusean incident ray of light at a first plurality of angles creating aplurality of first non-incident rays of light and a second particularsecond diffusion notch 322 of the plurality of second diffusion notches322 may be configured to diffuse a first non-incident ray of light ofthe plurality of first non-incident rays of light at a second pluralityof angles creating a plurality of second non-incident rays of light.

Illustratively, diffusion indentation 330 may be configured to diffuselight, e.g., diffusion indentation 330 may be configured to diffuselight by diffuse reflection. For example, diffusion indentation 330 maybe configured to diffuse an incident ray of light at a first pluralityof angles creating a plurality of first non-incident rays of light andsecond and diffusion notch 322 may be configured to diffuse a firstnon-incident ray of light of the plurality of first non-incident rays oflight at a second plurality of angles creating a plurality of secondnon-incident rays of light. In one or more embodiments, diffusionindentation distal gradient increase 333 may be configured to diffuselight, e.g., diffusion indentation distal gradient increase 333 may beconfigured to diffuse light by diffuse reflection. For example,diffusion indentation distal gradient increase 333 may be configured todiffuse an incident ray of light at a first plurality of angles creatinga plurality of first non-incident rays of light and second diffusionnotch 322 may be configured to diffuse a first non-incident ray of lightof the plurality of first non-incident rays of light at a secondplurality of angles creating a plurality of second non-incident rays oflight. Illustratively, diffusion indentation proximal gradient increase334 may be configured to diffuse light, e.g., diffusion indentationproximal gradient increase 334 may be configured to diffuse light bydiffuse reflection. For example, diffusion indentation proximal gradientincrease 334 may be configured to diffuse an incident ray of light at afirst plurality of angles creating a plurality of first non-incidentrays of light and second diffusion notch 322 may be configured todiffuse a first non-incident ray of light of the plurality of firstnon-incident rays of light at a second plurality of angles creating aplurality of second non-incident rays of light.

FIG. 3E illustrates an isometric view of diffuser 300. In one or moreembodiments, diffuser 300 may comprise a diffuser distal end 301, adiffuser proximal end 302, a third distal taper 313, a diffuser innerbore 315, and a diffusion taper 340. Illustratively, diffusion taper 340may comprise a diffusion taper distal end 341 and a diffusion taperproximal end 342. FIG. 3F illustrates a cross-sectional view in asagittal plane of diffuser 300. Illustratively, diffuser 300 maycomprise a third atraumatic offset 305 and a third diffusion notch 323.In one or more embodiments, third atraumatic offset 305 may beconfigured to reduce a risk of unintentional trauma during a surgicalprocedure. For example, third distal taper 312 may be configured toreduce a surface area of diffuser distal end 301 which may increase arisk of unintentional trauma during a surgical procedure, e.g., reducinga surface area of diffuser distal end 301 may increase a risk of cuttinga tissue during an aspiration of a surgical site. In one or moreembodiments, third atraumatic offset 305 may be configured to decrease arisk of cutting a tissue during an aspiration of a surgical site, e.g.,third atraumatic offset 305 may be configured to decrease a risk ofcutting a tissue during an aspiration of a surgical site by increasing asurface area of diffuser distal end 301. Illustratively, thirdatraumatic offset 305 may have a length in a range of 0.02 to 0.04inches, e.g., third atraumatic offset 305 may have a length of 0.03inches. In one or more embodiments, third atraumatic offset 305 may havea length of less than 0.02 inches or greater than 0.04 inches.

Illustratively, diffuser 300 may be configured to diffuse light, e.g.,diffuser 300 may be configured to diffuse light to illuminate a surgicalsite. In one or more embodiments, diffuser 300 may be configured todiffuse light by diffuse reflection. Illustratively, diffuser 300 may bemay be manufactured from any suitable material, e.g., polymers, metals,metal alloys, etc., or from any combination of suitable materials. Inone or more embodiments, diffuser 300 may be manufactured from amaterial configured to increase an efficiency of diffuse reflection.Illustratively, diffuser 300 may be manufactured from an opticallytransparent material, e.g., diffuser 300 may be manufactured frompolycarbonate, acrylic, etc. In one or more embodiments, diffuser 300may be manufactured from a material having an index of refraction thatis similar to an index of refraction of optic fiber bundle 850, e.g.,diffuser 300 may be manufactured from a material having an index ofrefraction that is not more than 10.0 to 30.0 percent less than an indexof refraction of optic fiber bundle 850. Illustratively, diffuser 300may be manufactured from a material having an index of refraction thatis not more than 10.0 to 30.0 percent greater than an index ofrefraction of optic fiber bundle 850. In one or more embodiments,diffuser 300 may be manufactured from a material having an index ofrefraction that is not more than 10.0 percent less than an index ofrefraction of optic fiber bundle 850, e.g., diffuser 300 may bemanufactured from a material having an index of refraction that is notmore than 10.0 percent greater than an index of refraction of opticfiber bundle 850. Illustratively, third diffusion notch 323 may beconfigured to diffuse light, e.g., third diffusion notch 323 may beconfigured to diffuse light by diffuse reflection. In one or moreembodiments, diffuser 300 may comprise a plurality of third diffusionnotches 323, e.g., diffuser 300 may comprise a plurality of thirddiffusion notches 323 wherein each third diffusion notch 323 of theplurality of third diffusion notches 323 is configured to diffuse light.For example, a first particular third diffusion notch 323 of theplurality of third diffusion notches 323 may be configured to diffuse anincident ray of light at a first plurality of angles creating aplurality of first non-incident rays of light and a second particularthird diffusion notch 323 of the plurality of third diffusion notches323 may be configured to diffuse a first non-incident ray of light ofthe plurality of first non-incident rays of light at a second pluralityof angles creating a plurality of second non-incident rays of light.Illustratively, diffusion taper 340 may be configured to diffuse light,e.g., diffusion taper 340 may be configured to diffuse light by diffusereflection. For example, diffusion taper 340 may be configured todiffuse an incident ray of light at a first plurality of angles creatinga plurality of first non-incident rays of light and third diffusionnotch 323 may be configured to diffuse a first non-incident ray of lightof the plurality of first non-incident rays of light at a secondplurality of angles creating a plurality of second non-incident rays oflight.

FIGS. 4A and 4B are schematic diagrams illustrating an aspirationconduit 400. FIG. 4A illustrates an isometric view of aspiration conduit400. In one or more embodiments, aspiration conduit 400 may comprise anaspiration conduit distal end 401, an aspiration conduit proximal end402, an outer tube 410, and an inner tube 420. FIG. 4B illustrates across-sectional view in a sagittal plane of aspiration conduit 400. Inone or more embodiments, outer tube 410 may comprise an outer tubedistal end 411 and an outer tube proximal end 412. Illustratively, innertube 420 may comprise an inner tube distal end 421 and an inner tubeproximal end 422. In one or more embodiments, a portion of inner tube420 may be disposed within a portion of outer tube 410, e.g., inner tubeproximal end 422 may be disposed within a portion of outer tube 410where in inner tube proximal end 422 is disposed between outer tubedistal end 411 and outer tube proximal end 412. Illustratively, innertube 420 may have an outer diameter in a range of 2.0 to 10.0 Fr, e.g.,inner tube 420 may have an outer diameter of 3.0 Fr. In one or moreembodiments, inner tube 420 may have an outer diameter less than 2.0 Fror greater than 10.0 Fr. Illustratively, a portion of inner tube 420 maybe fixed with in a portion of outer tube 410, e.g., a portion of innertube 420 may be fixed with in a portion of outer tube 410 by a frictionfit, an adhesive, a weld, etc. In one or more embodiments, a portion ofinner tube 420 may be disposed within a portion of outer tube 410wherein inner tube distal end 421 is aspiration conduit distal end 401and outer tube proximal end 412 is aspiration conduit proximal end 402.Illustratively, aspiration conduit 400 may be may be manufactured fromany suitable material, e.g., polymers, metals, metal alloys, etc., orfrom any combination of suitable materials.

FIGS. 5A, 5B, and 5C are schematic diagrams illustrating an assembledhandpiece 500. FIG. 5A illustrates a top view of assembled handpiece500. In one or more embodiments, assembled handpiece 500 may comprise anaspiration conduit 400 and a handle 100. FIG. 5B illustrates a side viewof assembled handpiece 500. Illustratively, aspiration conduit 400 maybe curved wherein aspiration conduit distal end 401 is disposed inferiorto aspiration conduit proximal end 402. In one or more embodiments,aspiration conduit 400 may be configured for use as a surgicalretractor, e.g., aspiration conduit 400 may have a rigidity configuredto retract and manipulate tissue during a surgical procedure. FIG. 5Cillustrates a cross-sectional view in a sagittal plane of assembledhand-piece 500. In one or more embodiments, a portion of aspirationconduit 400 may be disposed within a portion of handle 100, e.g.,aspiration conduit proximal end 402 may be disposed within handle distalchamber 115. Illustratively, a portion of aspiration conduit 400 may bedisposed within a portion of handle 100 wherein aspiration conduitproximal end 402 is adjacent to handle focused taper 116. In one or moreembodiments, a portion of aspiration conduit 400 may be fixed within aportion of handle 100, e.g., a portion of aspiration conduit 400 may befixed within a portion of handle 100 by a friction fit, an adhesive, aweld, etc.

FIGS. 6A and 6B are schematic diagrams illustrating a distal retainer600. FIG. 6A illustrates an isometric view of distal retainer 600. Inone or more embodiments, distal retainer 600 may comprise a distalretainer distal end 601, a distal retainer proximal end 602, and aretaining bevel 620. FIG. 6B illustrates a front view of distal retainer600. Illustratively, distal retainer 600 may comprise a medial bore 610,a first distal optic fiber housing 611, a second distal optic fiberhousing 612, a third distal optic fiber housing 613, and a fourth distaloptic fiber housing 614. In one or more embodiments, distal retainer 600may be configured to house a portion of optic fiber bundle 850, e.g.,distal retainer 600 may be configured to house optic fiber bundle distalend 851. For example, optic fiber bundle distal end 851 may be fixedwithin distal retainer 600, e.g., optic fiber bundle distal end 851 maybe fixed within distal retainer 600 by a friction fit, an adhesive, aweld, etc. Illustratively, retaining bevel 620 may be configured tohouse an optic fiber as a distal end of the optic fiber expands, e.g.,an optic fiber may be cleaved with a heated knife causing a distal endof the optic fiber to expand due to an application of thermal energy andretaining bevel 620 may be configured to house the optic fiber as thedistal end of the optic fiber expands. In one or more embodiments,medial bore 610 may be configured to facilitate an aspiration flow,e.g., aspiration targets may be configured to flow through medial bore610 after being aspirated out of a surgical site. In one or moreembodiments, distal retainer 600 may be may be manufactured from anysuitable material, e.g., polymers, metals, metal alloys, etc., or fromany combination of suitable materials.

FIGS. 7A and 7B are schematic diagrams illustrating a proximal retainer700. FIG. 7A illustrates an isometric view of proximal retainer 700. Inone or more embodiments, proximal retainer 700 may comprise a proximalcontainer distal end 701 and a proximal container proximal end 702. FIG.7B illustrates a front view of proximal retainer 700. In one or moreembodiments, proximal retainer 700 may comprise a first proximal opticfiber housing 711, a second proximal optic fiber housing 712, a thirdproximal optic fiber housing 713, and a fourth proximal optic fiberhousing 714. Illustratively, proximal retainer 700 may be configured tohouse a portion of optic fiber bundle 850, e.g., proximal retainer 700may be configured to house optic fiber bundle proximal end 852. In oneor more embodiments, optic fiber bundle proximal end 852 may be fixedwithin proximal retainer 700, e.g., optic fiber bundle proximal end 852may be fixed within proximal retainer 700 by a friction fit, anadhesive, a weld, etc. Illustratively, proximal retainer 700 may be maybe manufactured from any suitable material, e.g., polymers, metals,metal alloys, etc., or from any combination of suitable materials.

FIG. 8 is a schematic diagram illustrating an exploded view of anilluminated microsurgical probe assembly 800. In one or moreembodiments, an illuminated microsurgical probe assembly 800 maycomprise a proximal retainer 700, a light source interface 860, aproximal sleeve 830, a vacuum interface 880, an optic fiber bundle 850,an optic fiber bundle jacketing 840, an aspiration tube 820, a swivel200, a distal sleeve 810, a handle 100, an aspiration conduit 400, ahousing sleeve 870, a distal retainer 600, a diffuser 300, and a stylet890. Illustratively, light source interface 860 may comprise a lightsource interface distal end 861 and a light source interface proximalend 862. In one or more embodiments, light source interface 860 may beconfigured to interface with a surgical illumination machine to transmitlight from the surgical illumination machine through optic fiber bundle850. Illustratively, light source interface 860 may be may bemanufactured from any suitable material, e.g., polymers, metals, metalalloys, etc., or from any combination of suitable materials. In one ormore embodiments, proximal sleeve 830 may comprise a proximal sleevedistal end 831 and a proximal sleeve proximal end 832. Illustratively,proximal sleeve 830 may be configured to house a portion of light sourceinterface 860 and a portion of optic fiber bundle jacketing 840. In oneor more embodiments, proximal sleeve 830 may be configured to thermallyinsulate a portion of light source interface 860, e.g., proximal sleeve830 may be configured thermally insulate a user from a portion of lightsource interface 860. In one or more embodiments, proximal sleeve 830may be may be manufactured from any suitable material, e.g., polymers,metals, metal alloys, etc., or from any combination of suitablematerials. Illustratively, vacuum interface 880 may comprise a vacuuminterface distal end 881 and a vacuum interface proximal end 882. In oneor more embodiments, vacuum interface 880 may be configured to interfacewith a surgical vacuum machine to facilitate an aspiration of a surgicalsite. Illustratively, vacuum interface 880 may be may be manufacturedfrom any suitable material, e.g., polymers, metals, metal alloys, etc.,or from any combination of suitable materials.

In one or more embodiments, optic fiber bundle 850 may comprise an opticfiber bundle distal end 851 and an optic fiber bundle proximal end 852.Illustratively, optic fiber bundle 850 may be configured to transmitlight from a surgical illumination machine to a surgical site, e.g.,light from a surgical illumination machine may ingress optic fiberbundle 850 at optic fiber bundle distal end 852 and light from asurgical illumination machine may egress optic fiber bundle 850 at opticfiber bundle distal end 851. In one or more embodiments, optic fiberbundle 850 may comprise a single optic fiber. Illustratively, opticfiber bundle 850 may comprise a plurality of optic fibers. In one ormore embodiments, optic fiber bundle 850 may comprise a number of opticfibers in a range of 2 to 20, e.g., optic fiber bundle 850 may comprise4 optic fibers. Illustratively, optic fiber bundle 850 may comprise lessthan 2 optic fibers or greater than 20 optic fibers. In one or moreembodiments, optic fiber bundle 850 may comprise at least 2 optic fibersbut less than 20 optic fibers. For example, optic fiber bundle 850 maycomprise 3 optic fibers. In one or more embodiments, optic fiber bundle850 may comprise one or more optic fibers manufactured from glass, e.g.,optic fiber bundle 850 may comprise one or more optic fibersmanufactured from silica. Illustratively, optic fiber bundle 850 maycomprise one or more optic fibers manufactured from plastic, e.g., opticfiber bundle 850 may comprise one or more optic fibers manufactured fromPolymethyl Methacrylate Resin, Polystyrene, etc. In one or moreembodiments, optic fiber bundle 850 may comprise one or more opticfibers having a cladding material, e.g., optic fiber bundle 850 maycomprise one or more optic fibers having a cladding materialmanufactured from a fluorinated polymer, a silicone resin, etc.Illustratively, optic fiber bundle 850 may comprise one or more opticfibers having a step index refractive index profile. In one or moreembodiments, optic fiber bundle 850 may comprise one or more multi-modeoptic fibers, one or more single-mode optic fibers, etc. In one or moreembodiments, optic fiber bundle 850 may comprise one or more opticfibers having a core refractive index in a range of 1.3 to 1.8, e.g.,optic fiber bundle 850 may comprise one or more optic fibers having acore refractive index of 1.49. Illustratively, optic fiber bundle 850may comprise one or more optic fibers having a core refractive index ofless than 1.3 or greater than 1.8. In one or more embodiments, opticfiber bundle 850 may comprise one or more optic fibers having anumerical aperture in a range of 0.3 to 0.8, e.g., optic fiber bundle850 may comprise one or more optic fibers having a numerical aperture of0.5. In one or more embodiments, optic fiber bundle 850 may comprise oneor more optic fibers having a numerical aperture of less than 0.3 orgreater than 0.8. Illustratively, optic fiber bundle 850 may compriseone or more optic fibers having a core diameter in a range of 185 to 785micrometers, e.g., optic fiber bundle 850 may comprise one or more opticfibers having a core diameter of 485 micrometers. In one or moreembodiments, optic fiber bundle 850 may comprise one or more opticfibers having a core diameter of less than 185 micrometers or greaterthan 785 micrometers. Illustratively, optic fiber bundle 850 maycomprise one or more optic fibers having an overall diameter in a rangeof 200 to 800 micrometers, e.g., optic fiber bundle 850 may comprise oneor more optic fiber having an overall diameter of 500 micrometers. Inone or more embodiments, optic fiber bundle 850 may comprise one or moreoptic fibers having an overall diameter of less than 200 or greater than800 micrometers.

In one or more embodiments, optic fiber bundle jacketing 840 maycomprise an optic fiber bundle jacketing distal end 841 and an opticfiber bundle jacketing proximal end 842. Illustratively, optic fiberbundle jacketing 840 may be configured to house optic fiber bundle 850,e.g., optic fiber bundle jacketing 840 may be configured to protectoptic fiber bundle 850 from external forces during a surgical procedure.In one or more embodiments, optic fiber bundle jacketing 840 may be maybe manufactured from any suitable material, e.g., polymers, metals,metal alloys, etc., or from any combination of suitable materials.Illustratively, aspiration tube 820 may comprise an aspiration tubedistal end 821 and an aspiration tube proximal end 822. In one or moreembodiments, aspiration tube 820 may be configured to facilitate anaspiration of a surgical site. Illustratively, aspiration tube 820 maybe may be manufactured from any suitable material, e.g., polymers,metals, metal alloys, etc., or from any combination of suitablematerials. In one or more embodiments, distal sleeve 810 may comprise adistal sleeve distal end 811 and a distal sleeve proximal end 812.Illustratively, distal sleeve 810 may be configured to interface with aportion of handle 100 and a portion of swivel 200, e.g., distal sleeve810 may be configured to interface with handle proximal end 102 andswivel distal end 201. In one or more embodiments, distal sleeve 810 maybe configured to facilitate an aspiration of a surgical site.Illustratively, distal sleeve 810 may be may be manufactured from anysuitable material, e.g., polymers, metals, metal alloys, etc., or fromany combination of suitable materials.

In one or more embodiments, housing sleeve 870 may comprise a housingsleeve distal end 871 and a housing sleeve proximal end 872.Illustratively, housing sleeve 870 may be configured to house opticfiber bundle 850, optic fiber bundle jacketing 840, aspiration conduit400, distal retainer 600, and diffuser 300. In one or more embodiments,a portion of housing sleeve 870 may be configured to facilitate anaspiration of a surgical site. Illustratively, housing sleeve 870 may bemay be manufactured from any suitable material, e.g., polymers, metals,metal alloys, etc., or from any combination of suitable materials. Inone or more embodiments, stylet 890 may comprise a stylet distal end 891and a stylet proximal end 892. Illustratively, a portion of stylet 890may comprise a loop, e.g., stylet distal end 891 may comprise a loop. Inone or more embodiments, stylet 890 may be configured to remove debrisobstructing an aspiration flow within aspiration conduit 400. Forexample, aspiration conduit 400 may be configured to aspirate blood,surgical irrigation fluids, and tissue from a surgical site.Illustratively, blood clots and tissue may accumulate within aspirationconduit 400 reducing an aspiration flow rate at a surgical site. In oneor more embodiments, stylet 890 may be configured to breakup accumulateddebris within aspiration conduit 400, e.g., stylet proximal end 892 maybe configured to breakup accumulated blood clots and tissue withinaspiration conduit 400. Illustratively, stylet 890 may be manufacturedfrom any suitable material, e.g., polymers, metals, metal alloys, etc.,or from any combination of suitable materials.

FIG. 9 is a schematic diagram illustrating an assembled illuminatedmicrosurgical probe 900. In one or more embodiments, an assembledilluminated microsurgical probe 900 may comprise a proximal retainer700, a light source interface 860, a proximal sleeve 830, a vacuuminterface 880, an optic fiber bundle 850, an optic fiber bundlejacketing 840, an aspiration tube 820, a swivel 200, a distal sleeve810, a handle 100, an aspiration conduit 400, a housing sleeve 870, adistal retainer 600, a diffuser 300, and a stylet 890. Illustratively, aportion of proximal retainer 700 may be disposed within a portion oflight source interface 860, e.g., a portion of proximal retainer 700 maybe disposed within light source interface proximal end 862. In one ormore embodiments, a portion of proximal retainer 700 may be fixed withina portion of light source interface 860, e.g., a portion of proximalretainer 700 may be fixed within a portion of light source interface 860by a friction fit, an adhesive, a weld, etc. In one or more embodiments,a first portion of proximal retainer 700 may be fixed within a portionof light source interface 860 wherein a second portion of proximalretainer 700 extends from light source interface proximal end 862.Illustratively, a portion of distal retainer 600 may be disposed withina portion of diffuser 300, e.g., a portion of distal retainer 600 may bedisposed within diffuser proximal end 302. In one or more embodiments, aportion of distal retainer 600 may be disposed within a portion ofdiffuser 300 wherein distal retainer distal end 601 is disposed betweendiffuser distal end 301 and diffuser proximal end 302, e.g., a portionof distal retainer 600 may be disposed within diffuser 300 whereindistal retainer proximal end 602 is proximal to diffuser proximal end302. Illustratively, distal retainer 600 may be disposed within diffuser300 wherein distal retainer distal end 601 is disposed between diffuserdistal end 301 and diffuser proximal end 302, e.g., distal retainer 600may be disposed within diffuser 300 wherein distal retainer proximal end602 is disposed between diffuser distal end 301 and diffuser proximalend 302. In one or more embodiments, a portion of distal retainer 600may be fixed within a portion of diffuser 300, e.g., a portion of distalretainer 600 may be fixed within a portion of diffuser 300 by a frictionfit, an adhesive, a weld, etc. Illustratively, proximal sleeve 830 maybe disposed over a portion of light source interface 860, e.g., proximalsleeve 830 may be disposed over light source interface distal end 861.In one or more embodiments, proximal sleeve 830 may be fixed to aportion of light source interface 860, e.g., proximal sleeve 830 may befixed to a portion of light source interface 860 by a force of friction,an adhesive, etc.

Illustratively, optic fiber bundle 850 may be disposed in proximalretainer 700, light source interface 860, optic fiber bundle jacketing840, optic fiber bundle jacketing housing 110, housing sleeve 870,distal retainer 600, and diffuser 300. In one or more embodiments, opticfiber bundle 850 may be disposed in optic fiber bundle jacketing 840wherein a portion of optic fiber bundle 850 extends a distance fromoptic fiber bundle jacketing proximal end 842, e.g., optic fiber bundle850 may be disposed in optic fiber bundle jacketing 840 wherein opticfiber bundle proximal end 852 extends a distance from optic fiber bundlejacketing proximal end 842. Illustratively, optic fiber bundle 850 maybe disposed in optic fiber bundle jacketing 840 wherein a portion ofoptic fiber bundle 850 extends a distance from optic fiber bundlejacketing distal end 841, e.g., optic fiber bundle 850 may be disposedin optic fiber bundle jacketing 840 wherein optic fiber bundle distalend 851 extends a distance from optic fiber bundle jacketing distal end841.

In one or more embodiments, optic fiber bundle 850 may be disposed inoptic fiber bundle jacketing 840 wherein a portion of optic fiber bundle850 is disposed in optic fiber bundle jacketing housing 110, e.g., aportion of optic fiber bundle jacketing 840 may be disposed in opticfiber bundle jacketing housing 110. Illustratively, optic fiber bundlejacketing 840 may be disposed within optic fiber bundle jacketinghousing 110 wherein a portion of optic fiber jacketing 840 extends outfrom optic fiber bundle jacketing housing distal end 111, e.g., opticfiber bundle jacketing 840 may be disposed within optic fiber bundlejacketing housing 110 wherein optic fiber jacketing distal end 841extends out from optic fiber bundle jacketing housing distal end 111. Inone or more embodiments, optic fiber bundle jacketing 840 may bedisposed within optic fiber bundle jacketing housing 110 wherein aportion of optic fiber jacketing 840 extends out from optic fiber bundlejacketing housing proximal end 112, e.g., optic fiber bundle jacketing840 may be disposed within optic fiber bundle jacketing housing 110wherein optic fiber jacketing proximal end 842 extends out from opticfiber bundle jacketing housing proximal end 112.

In one or more embodiments, optic fiber bundle 850 may be disposed inlight source interface 860 wherein a portion of optic fiber bundle 850is disposed in proximal retainer 700, e.g., optic fiber bundle 850 maybe disposed in light source interface 860 wherein optic fiber bundleproximal end 852 is disposed in proximal retainer 700. Illustratively,optic fiber bundle 850 may be disposed in light source interface 860wherein one or more optic fibers of optic fiber bundle 850 may bedisposed in first proximal optic fiber housing 711. In one or moreembodiments, optic fiber bundle 850 may be disposed in light sourceinterface 860 wherein one or more optic fibers of optic fiber bundle 850may be fixed within first proximal optic fiber housing 711, e.g., one ormore optic fibers of optic fiber bundle 850 may be fixed within firstproximal optic fiber housing 711 by a force of friction, an adhesive, acrimp, etc. Illustratively, optic fiber bundle 850 may be disposed inlight source interface 860 wherein one or more optic fibers of opticfiber bundle 850 may be disposed in second proximal optic fiber housing712. In one or more embodiments, optic fiber bundle 850 may be disposedin light source interface 860 wherein one or more optic fibers of opticfiber bundle 850 may be fixed within second proximal optic fiber housing712, e.g., one or more optic fibers of optic fiber bundle 850 may befixed within second proximal optic fiber housing 712 by a force offriction, an adhesive, a crimp, etc. Illustratively, optic fiber bundle850 may be disposed in light source interface 860 wherein one or moreoptic fibers of optic fiber bundle 850 may be disposed in third proximaloptic fiber housing 713. In one or more embodiments, optic fiber bundle850 may be disposed in light source interface 860 wherein one or moreoptic fibers of optic fiber bundle 850 may be fixed within thirdproximal optic fiber housing 713, e.g., one or more optic fibers ofoptic fiber bundle 850 may be fixed within third proximal optic fiberhousing 713 by a force of friction, an adhesive, a crimp, etc.Illustratively, optic fiber bundle 850 may be disposed in light sourceinterface 860 wherein one or more optic fibers of optic fiber bundle 850may be disposed in fourth proximal optic fiber housing 714. In one ormore embodiments, optic fiber bundle 850 may be disposed in light sourceinterface 860 wherein one or more optic fibers of optic fiber bundle 850may be fixed within fourth proximal optic fiber housing 714, e.g., oneor more optic fibers of optic fiber bundle 850 may be fixed withinfourth proximal optic fiber housing 714 by a force of friction, anadhesive, a crimp, etc.

Illustratively, optic fiber bundle 850 may be disposed in housing sleeve870, e.g., optic fiber bundle 850 may ingress housing sleeve 870 athousing sleeve opening 910. In one or more embodiments, optic fiberbundle 850 may be disposed in housing sleeve 870 wherein a portion ofoptic fiber bundle 850 is disposed in distal retainer 600, e.g., opticfiber bundle 850 may be disposed in housing sleeve 870 wherein opticfiber bundle distal end 851 is disposed in distal retainer 600.Illustratively, optic fiber bundle 850 may be disposed in housing sleeve870 wherein one or more optic fibers of optic fiber bundle 850 may bedisposed in first distal optic fiber housing 611. In one or moreembodiments, optic fiber bundle 850 may be disposed in housing sleeve870 wherein one or more optic fibers of optic fiber bundle 850 may befixed within first distal optic fiber housing 611, e.g., one or moreoptic fibers of optic fiber bundle 850 may be fixed within first distaloptic fiber housing 611 by a force of friction, an adhesive, a crimp,etc. Illustratively, optic fiber bundle 850 may be disposed in housingsleeve 870 wherein one or more optic fibers of optic fiber bundle 850may be disposed in second distal optic fiber housing 612. In one or moreembodiments, optic fiber bundle 850 may be disposed in housing sleeve870 wherein one or more optic fibers of optic fiber bundle 850 may befixed within second distal optic fiber housing 612, e.g., one or moreoptic fibers of optic fiber bundle 850 may be fixed within second distaloptic fiber housing 612 by a force of friction, an adhesive, a crimp,etc. Illustratively, optic fiber bundle 850 may be disposed in housingsleeve 870 wherein one or more optic fibers of optic fiber bundle 850may be disposed in third distal optic fiber housing 613. In one or moreembodiments, optic fiber bundle 850 may be disposed in housing sleeve870 wherein one or more optic fibers of optic fiber bundle 850 may befixed within third distal optic fiber housing 613, e.g., one or moreoptic fibers of optic fiber bundle 850 may be fixed within third distaloptic fiber housing 613 by a force of friction, an adhesive, a crimp,etc. Illustratively, optic fiber bundle 850 may be disposed in housingsleeve 870 wherein one or more optic fibers of optic fiber bundle 850may be disposed in fourth distal optic fiber housing 614. In one or moreembodiments, optic fiber bundle 850 may be disposed in housing sleeve870 wherein one or more optic fibers of optic fiber bundle 850 may befixed within fourth distal optic fiber housing 614, e.g., one or moreoptic fibers of optic fiber bundle 850 may be fixed within fourth distaloptic fiber housing 614 by a force of friction, an adhesive, a crimp,etc.

Illustratively, aspiration conduit 400 may be disposed in handle 100 andin housing sleeve 870. In one or more embodiments, aspiration conduit400 may be disposed in housing sleeve 870 wherein a portion ofaspiration conduit 400 is disposed in distal retainer 600, e.g.,aspiration conduit 400 may be disposed in housing sleeve 870 whereinaspiration conduit distal end 401 is disposed in medial bore 610.Illustratively, aspiration conduit 400 may be disposed in housing sleeve870 wherein a portion of aspiration conduit is fixed within a portion ofdistal retainer 600, e.g., aspiration conduit 400 may be disposed inhousing sleeve 870 wherein aspiration conduit distal end 401 is fixedwithin medial bore 610 by a friction fit, an adhesive, a weld, etc. Inone or more embodiments, aspiration conduit 400 may be disposed inhousing sleeve 870 wherein a portion of aspiration conduit is disposedin diffuser 300, e.g., aspiration conduit 400 may be disposed in housingsleeve 870 wherein aspiration conduit distal end 401 is disposed indiffuser inner bore 315. Illustratively, aspiration conduit 400 may bedisposed in diffuser 300 wherein aspiration conduit distal end 401 isdisposed between diffuser distal end 301 and distal proximal end 302. Inone or more embodiments, aspiration conduit 400 may be disposed indiffuser 300 wherein aspiration conduit distal end 401 is adjacent tofirst atraumatic offset 303. Illustratively, aspiration conduit 400 maybe disposed in diffuser 300 wherein aspiration conduit distal end 401 isadjacent to second atraumatic offset 304. In one or more embodiments,aspiration conduit 400 may be disposed in diffuser 300 whereinaspiration conduit distal end 401 is adjacent to third atraumatic offset305. Illustratively, aspiration conduit 400 may be disposed in housingsleeve 870 wherein a portion of aspiration conduit 400 may be fixedwithin a portion of diffuser 300, e.g., aspiration conduit 400 may bedisposed in housing sleeve 870 wherein aspiration conduit distal end 401is fixed within diffuser inner bore 315 by a friction fit, an adhesive,a weld, etc. In one or more embodiments, optic fiber bundle 850 may bedisposed in aspiration conduit 400, e.g., optic fiber bundle 850 may bedisposed in aspiration conduit 400 wherein optic fiber bundle distal end850 extends a distance from conduit distal end 401. Illustratively,optic fiber bundle 850 may be disposed in housing sleeve 870 and notdisposed in aspiration conduit 400, e.g., optic fiber bundle 850 may bedisposed in housing sleeve 870 wherein a portion of optic fiber bundle850 is adjacent to a portion of aspiration conduit 400.

In one or more embodiments, a portion of handle 100 may be disposed in aportion of distal sleeve 810, e.g., a portion of handle 100 may bedisposed in in a portion of distal sleeve 810 wherein handle proximalend 102 is disposed in distal sleeve distal end 811. Illustratively, aportion of handle 100 may be disposed in a portion of distal sleeve 810wherein barb 103 is disposed in distal sleeve distal end 811. Forexample, barb 103 may comprise a luer fitting and a portion of distalsleeve 810 may be configured to attach by barb 103 by a luer lock. Inone or more embodiments, a portion of handle 100 may be fixed withindistal sleeve 810, e.g., handle proximal end 102 may be fixed withindistal sleeve 810 by a force of friction, a tie, a crimp, an adhesive,etc. Illustratively, a portion of handle 100 may be disposed in aportion of distal sleeve 810 wherein distal sleeve distal end 811 isadjacent to distal sleeve interface 104, e.g., a portion of handle 100may be disposed in a portion of distal sleeve 810 wherein distal sleevedistal end 811 is fixed to distal sleeve interface 104 by an adhesive, aweld, etc. In one or more embodiments, a portion of handle 100 may bedisposed in a portion of distal sleeve 810 wherein a portion of handleproximal chamber 118 is disposed in distal sleeve 810, e.g., a portionof handle 100 may be disposed in a portion of distal sleeve 810 whereina portion of handle proximal chamber 118 is disposed in distal sleevedistal end 811.

Illustratively, a portion of swivel 200 may be disposed in a portion ofdistal sleeve 810, e.g., swivel distal end 201 may be disposed in distalsleeve proximal end 812. In one or more embodiments, a portion of swivel200 may be disposed in a portion of distal sleeve 810 wherein a portionof outer swivel component 210 is disposed in a portion of distal sleeve810, e.g., a portion of swivel 200 may be disposed in a portion ofdistal sleeve 810 wherein outer swivel component distal end 211 isdisposed in distal sleeve proximal end 812. Illustratively, a portion ofswivel 200 may be fixed within a portion of distal sleeve 810, e.g., aportion of swivel 200 may be fixed within a portion of distal sleeve 810by a force of friction, an adhesive, a crimp, etc. In one or moreembodiments, a portion of swivel 200 may be disposed in a portion ofdistal sleeve 810 wherein a portion of outer swivel component inner bore215 is disposed in a portion of distal sleeve 810. Illustratively, aportion of swivel 200 may be disposed in a portion of aspiration tube820, e.g., swivel proximal end 202 may be disposed in aspiration tubedistal end 821. In one or more embodiments, a portion of swivel 200 maybe disposed in a portion of aspiration tube 820 wherein a portion ofinner swivel component 220 is disposed in a portion of aspiration tube820, e.g., a portion of swivel 200 may be disposed in a portion ofaspiration tube 820 wherein inner swivel component proximal end 222 isdisposed in aspiration tube distal end 821. Illustratively, a portion ofswivel 200 may be fixed within a portion of aspiration tube 820, e.g., aportion of swivel 200 may be fixed within a portion of aspiration tube820 by a force of friction, an adhesive, a crimp, etc. In one or moreembodiments, a portion of swivel 200 may be disposed in a portion ofaspiration tube 820 wherein a portion of inner swivel component innerbore 225 is disposed in a portion of aspiration tube 820.

Illustratively, a portion of vacuum interface 880 may be disposed in aportion of aspiration tube 820, e.g., vacuum interface distal end 881may be disposed in aspiration tube proximal end 822. In one or moreembodiments, a portion of vacuum interface 880 may be fixed within aportion of aspiration tube 820, e.g., a portion of vacuum interface 880may be fixed within a portion of aspiration tube 820 by a force offriction, an adhesive, a crimp, etc. Illustratively, a portion ofaspiration conduit 400 may be disposed in a portion of diffuser 300,e.g., aspiration conduit distal end 401 may be disposed in diffuserproximal end 302. In one or more embodiments, aspiration conduit 400 maybe disposed in diffuser 300 and in distal retainer 600, e.g., aspirationconduit 400 may be disposed in diffuser inner bore 315 and medial bore610. Illustratively, a portion of aspiration conduit 400 may be fixedwithin a portion of diffuser 300, e.g., a portion of aspiration conduit400 may be fixed within a portion of diffuser 300 by an adhesive, afriction fit, a set-screw, etc. In one or more embodiments, a portion ofaspiration conduit 400 may be fixed within a portion of distal retainer600, e.g., a portion of aspiration conduit 400 may be fixed within aportion of distal retainer 600 by an adhesive, a friction fit, asetscrew, etc. Illustratively, a portion of stylet 890 may be disposedin diffuser 300, distal retainer 600, and aspiration conduit 400, e.g.,a portion of stylet 890 may be disposed in diffuser inner bore 315,medial bore 610, and aspiration conduit distal end 401. In one or moreembodiments, stylet 890 may not be fixed within diffuser 300, distalretainer 600, or aspiration conduit 400, e.g., stylet 890 may beremovable from diffuser inner bore 315, medial bore 610, and aspirationconduit 400.

In one or more embodiments, assembled illuminated microsurgical probe900 may be configured to remove an aspiration target, e.g., blood,irrigation fluid, bone, tissue, etc., from a surgical site.Illustratively, vacuum interface 880 may be configured to interface witha surgical vacuum machine to decrease a pressure within aspiration tube820. In one or more embodiments, decreasing a pressure within aspirationtube 820 may be configured to decrease a pressure within swivel 200.Illustratively, decreasing a pressure within swivel 200 may beconfigured to decrease a pressure within distal sleeve 810. In one ormore embodiments, decreasing a pressure within distal sleeve 810 may beconfigured to decrease a pressure within handle 100. Illustratively,decreasing a pressure within handle 100 may be configured to decrease apressure within aspiration conduit 400. In one or more embodiments,decreasing a pressure within aspiration conduit 400 may be configured todecrease a pressure within diffuser 300. Illustratively, decreasing apressure within diffuser 300 may be configured to remove an aspirationtarget from a surgical site.

In one or more embodiments, a surgeon may manipulate assembledilluminated microsurgical probe 900 to actuate diffuser distal end 301towards an aspiration target during a surgical procedure.Illustratively, vacuum interface 880 may be configured to interface witha surgical vacuum machine to decrease a pressure within diffuser 300wherein the pressure within diffuser 300 is less than an ambientpressure in a surgical site. In one or more embodiments, a pressurewithin diffuser 300 may be configured to cause the aspiration target toegress the surgical site and ingress diffuser inner bore 315. In one ormore embodiments, a pressure within aspiration conduit 400 may beconfigured to cause the aspiration target to egress diffuser inner bore315 and ingress aspiration conduit 400. Illustratively, a pressurewithin handle 100 may be configured to cause the aspiration target toegress aspiration conduit 400 and ingress handle distal chamber 115. Inone or more embodiments, a pressure within handle inner bore 117 may beconfigured to cause the aspiration target to egress handle distalchamber 115 and ingress handle inner bore 117. Illustratively, apressure within handle proximal chamber 118 may be configured to causethe aspiration target to egress handle inner bore 117 and ingress handleproximal chamber 118. In one or more embodiments, a pressure withindistal sleeve 810 may be configured to cause the aspiration target toegress handle proximal chamber 118 and ingress distal sleeve 810.Illustratively, a pressure within swivel 200 may be configured to causethe aspiration target to egress distal sleeve 810 and ingress outerswivel component inner bore 215. In one or more embodiments, a pressurewithin inner swivel component inner bore 225 may be configured to causethe aspiration target to egress outer swivel component inner bore 215and ingress inner swivel component inner bore 225. Illustratively, apressure within aspiration tube 820 may be configured to cause theaspiration target to egress inner swivel component inner bore 225 andingress aspiration tube 820.

In one or more embodiments, swivel 200 may be configured to prevent atorqueing of aspiration tube 820, e.g., a surgeon may rotate handle 100about a medial axis of handle 100 without torqueing aspiration tube 820.Illustratively, swivel 200 may be configured to rotate outer swivelcomponent 210 relative to inner swivel component 220 in response to arotation of handle 100 about a medial axis of handle 100, e.g., swivel200 may be configured to rotate inner swivel component 220 relative toouter swivel component 210 in response to a rotation of handle 100 abouta medial axis of handle 100. In one or more embodiments, swivel 200 maybe configured to prevent a torqueing of aspiration tube 820 withoutdecreasing an aspiration flow rate between handle 100 and aspirationtube 820, e.g., swivel 200 may be configured to prevent a torqueing ofaspiration tube 820 without increasing an aspiration flow rate betweenhandle 100 and aspiration tube 820.

Illustratively, a surgeon may manipulate an aspiration flow rate ofassembled illuminated microsurgical probe 900, e.g., a surgeon maymanipulate an aspiration flow rate of assembled illuminatedmicrosurgical probe 900 by modifying one or more settings of a surgicalvacuum machine. In one or more embodiments, a surgeon may manipulate anaspiration flow rate of assembled illuminated microsurgical probe 900 byselectively closing vent 105, e.g., a surgeon may manipulate anaspiration flow rate of assembled illuminated microsurgical probe 900 byselectively opening vent 105. Illustratively, vent 105 is normally open.In one or more embodiments, a surgeon may partially close vent 105 bypartially covering vent 105, e.g., a surgeon may partially close vent105 by partially covering vent 105 with the surgeon's thumb, finger,palm, etc. Illustratively, a surgeon my fully close vent 105 by fullycovering vent 105, e.g., a surgeon may fully close vent 105 by fullycovering vent 105 with the surgeon's thumb, finger, palm, etc. In one ormore embodiments, vacuum interface 880 may be configured to interfacewith a surgical vacuum machine to decrease a pressure within handle 100wherein the pressure with-in handle 100 is less than an ambient pressurein a surgical site. Illustratively, a surgeon may increase a pressurewithin handle 100 by opening vent 105, e.g., a surgeon my increase apressure within handle 100 by uncovering a covered portion of vent 105.In one or more embodiments, increasing a pressure within handle 100 maybe configured to decrease an aspiration flow rate of assembledilluminated microsurgical probe 900, e.g., a surgeon may decrease anaspiration flow rate of assembled illuminated microsurgical probe 900 byuncovering a covered portion of vent 105. Illustratively, a surgeon maydecrease a pressure within handle 100 by closing vent 105, e.g., asurgeon may decrease a pressure within handle 100 by covering anuncovered portion of vent 105. In one or more embodiments, decreasing apressure within handle 100 may be configured to increase an aspirationflow rate of assembled illuminated microsurgical probe 900, e.g., asurgeon may increase an aspiration flow rate of assembled illuminatedmicrosurgical probe 900 by covering an uncovered portion of vent 105.

In one or more embodiments, assembled illuminated microsurgical probe900 may be configured to illuminate a surgical site. Illustratively,optic fiber bundle 850 may be configured to receive light from asurgical illumination machine, e.g., optic fiber bundle proximal end 852may be configured to receive light from a surgical illumination machine.In one or more embodiments, optic fiber bundle 850 may be configured totransmit light from a surgical illumination machine to diffuser 300,e.g., optic fiber bundle distal end 851 may be configured to deliverlight from a surgical illumination machine to diffuser 300.Illustratively, diffuser 300 may be configured to diffuse light from asurgical illumination machine to illuminate a surgical site. In one ormore embodiments, a surgical illumination machine may comprise astandard endoscopy light source. For example, a surgical illuminationmachine may comprise a light source intended for use with an endoscopein endoscopy procedures. In one or more embodiments, an inner portion ofoptic fiber bundle jacketing 840 may comprise a reflective surfaceconfigured to reflect light. Illustratively, an inner portion of housingsleeve 870 may comprise a reflective surface configured to reflectlight. In one or more embodiments, assembled illuminated microsurgicalprobe 900 may be configured to illuminate a surgical site whereindiffuser 300 emits at least 25.0 lumens. Illustratively, assembledilluminated microsurgical probe 900 may be configured to illuminate asurgical site wherein a temperature of diffuser 300 does not exceed 74.0degrees Fahrenheit. In one or more embodiments, assembled illuminatedmicrosurgical probe 900 may be configured to illuminate a surgical sitewherein diffuser 300 emits at least 25.0 lumens and wherein atemperature of diffuser 300 does not exceed 74.0 degrees Fahrenheit.Illustratively, assembled illuminated microsurgical probe 900 may beconfigured to illuminate a surgical site wherein diffuser 300 emits in arange of 20.0 to 75.0 lumens, e.g., assembled illuminated microsurgicalprobe 900 may be configured to illuminate a surgical site whereindiffuser 300 emits 50.0 lumens. In one or more embodiments, assembledilluminated microsurgical probe 900 may be configured to illuminate asurgical site wherein diffuser 300 emits less than 20.0 lumens orgreater than 75.0 lumens.

The foregoing description has been directed to particular embodiments ofthis invention. It will be apparent; however, that other variations andmodifications may be made to the described embodiments, with theattainment of some or all of their advantages. Specifically, it shouldbe noted that the principles of the present invention may be implementedin any system. Furthermore, while this description has been written interms of an illuminated microsurgical probe, the teachings of thepresent invention are equally suitable to any systems where thefunctionality may be employed. Therefore, it is the object of theappended claims to cover all such variations and modifications as comewithin the true spirit and scope of the invention.

1. An instrument comprising: a handle having a handle distal end and ahandle proximal end; an inner bore of the handle, the inner boreextending from the handle distal end to the handle proximal end; adiffuser having a diffuser distal end, a diffuser proximal end, and adiffuser inner bore; an aspiration conduit having an aspiration conduitdistal end and an aspiration conduit proximal end wherein the aspirationconduit distal end is disposed in the diffuser inner bore and theaspiration conduit proximal end is disposed in the inner bore of thehandle; and an optic fiber bundle having an optic fiber bundle distalend and an optic fiber bundle proximal end, the optic fiber distal enddisposed in the diffuser inner bore.
 2. The instrument of claim 1further comprising: a vent of the handle having a vent distal end and avent proximal end, the vent configured to manipulate a pressure withinthe handle inner bore.
 3. The instrument of claim 1 further comprising:a light source interface having a light source interface distal end anda light source interface proximal end, the light source configured tointerface with a surgical illumination machine.
 4. The instrument ofclaim 3 further comprising: a proximal retainer having a proximalretainer distal end and a proximal retainer proximal end, the proximalretainer disposed in the light source interface wherein the optic fiberbundle proximal end is disposed in the proximal retainer.
 5. Theinterment of claim 1 wherein the optic fiber bundle comprises a singleoptic fiber.
 6. The instrument of claim 1 wherein the optic fiber bundlecomprises a plurality of optic fibers.
 7. The instrument of claim 6wherein the optic fiber bundle comprises at least two optic fibers andless than twenty optic fibers.
 8. The instrument of claim 1 furthercomprising: an aspiration tube having an aspiration tube distal end andan aspiration tube proximal end, the aspiration tube configured tofacilitate an aspiration of a surgical site; and a swivel having aswivel distal end and a swivel proximal end, the swivel configured toprevent a torqueing of the aspiration tube.
 9. The instrument of claim 8further comprising: an outer swivel component of the swivel having anouter swivel component distal end and an outer swivel component proximalend; and an inner swivel component of the swivel having an inner swivelcomponent distal end and an inner swivel component proximal end.
 10. Theinstrument of claim 9 wherein the outer swivel component is configuredto rotate relative to the inner swivel component.
 11. The instrument ofclaim 9 wherein the inner swivel component is configured to rotaterelative to the outer swivel component.
 12. The instrument of claim 1further comprising: a distal retainer having a distal retainer distalend and a distal retainer proximal end, the distal retainer disposed inthe diffuser inner bore wherein the optic fiber bundle distal end isdisposed in the distal retainer.
 13. The instrument of claim 12 whereinthe aspiration conduit is disposed in a medial bore of the distalretainer.
 14. The instrument of claim 1 further comprising: anatraumatic offset of the diffuser, the atraumatic offset configured toincrease a surface area of a portion of the diffuser.
 15. The instrumentof claim 1 further comprising: a diffusion notch of the diffuser, thediffusion notch configured to diffuse light by diffuse reflection. 16.The instrument of claim 1 further comprising: a plurality of diffusionnotches of the diffuser, each diffusion notch of the plurality ofdiffusion notches configured to diffuse light by diffuse reflection. 17.The instrument of claim 1 further comprising: a diffusion indentation ofthe diffuser, the diffusion indentation configured to diffuse light bydiffuse reflection.
 18. The instrument of claim 1 further comprising: adiffusion taper of the diffuser, the diffusion taper configured todiffuse light by diffuse reflection.
 19. An instrument comprising: ahandle having a handle distal end and a handle proximal end; an innerbore of the handle, the inner bore extending from the handle distal endto the handle proximal end; a vent of the handle having a vent distalend and a vent proximal end, the vent configured to manipulate apressure within the handle inner bore; a diffuser having a diffuserdistal end, a diffuser proximal end, and a diffuser inner bore; anaspiration conduit having an aspiration conduit distal end and anaspiration conduit proximal end wherein the aspiration conduit distalend is disposed in the diffuser inner bore and the aspiration conduitproximal end is disposed in the inner bore of the handle; an optic fiberbundle having an optic fiber bundle distal end and an optic fiber bundleproximal end, the optic fiber distal end disposed in the diffuser innerbore; and is a distal retainer having a distal retainer distal end and adistal retainer proximal end, the distal retainer disposed the diffuserinner bore wherein the optic fiber bundle distal end is disposed in thedistal retainer.
 20. An instrument comprising: a handle having a handledistal end and a handle proximal end; an inner bore of the handle, theinner bore extending from the handle distal end to the handle proximalend; a diffuser having a diffuser distal end, a diffuser proximal end,and a diffuser inner bore; an aspiration conduit having an aspirationconduit distal end and an aspiration conduit proximal end wherein theaspiration conduit distal end is disposed in the diffuser inner bore andthe aspiration conduit proximal end is disposed in the inner bore of thehandle; a light source interface having a light source interface distalend and a light source interface proximal end, the light sourceconfigured to interface with a surgical illumination machine; an opticfiber bundle having an optic fiber bundle distal end and an optic fiberbundle proximal end, the optic fiber distal end disposed in the diffuserinner bore; and a proximal retainer having a proximal retainer distalend and a proximal retainer proximal end, the proximal retainer disposedin the light source interface wherein the optic fiber bundle proximalend is disposed in the proximal retainer.